package batteries
A community-maintained standard library extension
Install
Dune Dependency
Authors
Maintainers
Sources
v3.9.0.tar.gz
md5=ea26b5c72e6731e59d856626049cca4d
sha512=55975b62c26f6db77433a3ac31f97af609fc6789bb62ac38b267249c78fd44ff37fe81901f1cf560857b9493a6046dd37b0d1c0234c66bd59e52843aac3ce6cb
doc/src/batteries.unthreaded/batDllist.ml.html
Source file batDllist.ml
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See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA *) type 'a node_t = { mutable data : 'a; mutable next : 'a node_t; mutable prev : 'a node_t } type 'a enum_t = { mutable curr : 'a node_t; mutable valid : bool } type 'a t = 'a node_t type 'a mappable = 'a t type 'a enumerable = 'a t exception Empty let invariants t = assert (t.next.prev == t && t.prev.next == t); let current = ref t.next in while !current != t do let t = !current in assert (t.next.prev == t && t.prev.next == t); current := t.next done let create x = let rec nn = { data = x; next = nn; prev = nn} in nn let length node = let rec loop cnt n = if n == node then cnt else loop (cnt + 1) n.next in loop 1 node.next let add node elem = let nn = { data = elem; next = node.next; prev = node } in node.next.prev <- nn; node.next <- nn (*$T add let t = of_list [1;2;3] in add t 12; invariants t; to_list t = [1;12;2;3] let t = of_list [1] in add t 2; invariants t; to_list t = [1;2] *) let append node elem = let nn = { data = elem; next = node.next; prev = node } in node.next.prev <- nn; node.next <- nn; nn let prepend node elem = let nn = { data = elem; next = node; prev = node.prev } in node.prev.next <- nn; node.prev <- nn; nn let promote node = let next = node.next in let prev = node.prev in if next != prev then begin next.next.prev <- node; node.next <- next.next; node.prev <- next; next.next <- node; next.prev <- prev; prev.next <- next end (*$T promote let t = of_list [1;2;3;4] in promote t; invariants t; to_list t = [1;3;4;2] let t = of_list [1] in promote t; invariants t; to_list t = [1] *) let demote node = let next = node.next in let prev = node.prev in if next != prev then begin prev.prev.next <- node; node.prev <- prev.prev; node.next <- prev; prev.prev <- node; prev.next <- next; next.prev <- prev end (*$T demote let t = of_list [1;2;3;4] in demote t; invariants t; to_list t = [1;4;2;3] let t = of_list [1] in demote t; invariants t; to_list t = [1] *) let remove node = let next = node.next in if next == node then raise Empty; (* singleton list points to itself for next *) let prev = node.prev in (* Remove node from list by linking prev and next together *) prev.next <- next; next.prev <- prev; (* Make node a singleton list by setting its next and prev to itself *) node.next <- node; node.prev <- node (*$T remove let t = of_list [1;2;3;4] in let u = next t in remove t; invariants u; to_list u = [2;3;4] let t = of_list [1;2] in let u = next t in remove t; invariants u; to_list u = [2] let t = of_list [1;2] in let u = next t in remove t; try remove u; false with Empty -> true let t = of_list [1] in try remove t; false with Empty -> true *) let drop node = let next = node.next in if next == node then raise Empty; (* singleton list points to itself for next *) let prev = node.prev in prev.next <- next; next.prev <- prev; node.next <- node; node.prev <- node; next (*$T drop let t = of_list [1;2;3;4] in let t = drop t in invariants t; to_list t = [2;3;4] let t = of_list [1] in try ignore (drop t); false with Empty -> true *) let rev_drop node = let next = node.next in if next == node then raise Empty; (* singleton list points to itself for next *) let prev = node.prev in prev.next <- next; next.prev <- prev; node.next <- node; node.prev <- node; prev (*$T rev_drop let t = of_list [1;2;3;4] in let t = rev_drop t in invariants t; to_list t = [4;2;3] let t = of_list [1] in try ignore (rev_drop t); false with Empty -> true *) let splice node1 node2 = let next = node1.next in let prev = node2.prev in node1.next <- node2; node2.prev <- node1; next.prev <- prev; prev.next <- next let set node data = node.data <- data let get node = node.data let next node = node.next let prev node = node.prev let skip node idx = let f = if idx > 0 then next else prev in let rec loop idx n = if idx == 0 then n else loop (idx - 1) (f n) in loop (abs idx) node let rev node = let rec loop next n = begin let prev = n.prev in n.next <- prev; n.prev <- next; if n != node then loop n prev end in loop node node.prev (*$T rev let t = of_list [1] in rev t; invariants t; to_list t = [1] let t = of_list [1;2;3;4] in rev t; invariants t; to_list t = [1;4;3;2] *) let iter f node = let () = f node.data in let rec loop n = if n != node then let () = f n.data in loop n.next in loop node.next let for_all p node = let rec loop n = if n == node then true else p n.data && loop n.next in p node.data && loop node.next let find p node = let rec loop n = if n == node then raise Not_found else if p n.data then n else loop n.next in if p node.data then node else loop node.next (*$T find find (fun x -> x mod 2 = 0) (of_list [1;3;4;5;7;6]) |> get = 4 find (fun x -> x = 1) (of_list [1;3;4;5;7;6]) |> get = 1 find (fun x -> x > 3) (of_list [-1;3;9;1;1;1]) |> get = 9 try find (fun x -> x land 3 = 2) (of_list [1;4;3])|>ignore; false with Not_found -> true *) (*qtest TODO: migrate try into an exception test *) let exists p node = let rec loop n = if n == node then false else p n.data || loop n.next in p node.data || loop node.next let fold_left f init node = let rec loop accu n = if n == node then accu else loop (f accu n.data) n.next in loop (f init node.data) node.next let fold_right f node init = let rec loop accu n = if n == node then f n.data accu else loop (f n.data accu) n.prev in loop init node.prev let map f node = let first = create (f node.data) in let rec loop last n = if n == node then begin first.prev <- last; first end else begin let nn = { data = f n.data; next = first; prev = last } in last.next <- nn; loop nn n.next end in loop first node.next let copy node = map (fun x -> x) node let to_list node = fold_right (fun d l -> d::l) node [] let of_list lst = match lst with | [] -> raise Empty | h :: t -> let first = create h in let rec loop last = function | [] -> last.next <- first; first.prev <- last; first | h :: t -> let nn = { data = h; next = first; prev = last } in last.next <- nn; loop nn t in loop first t (*$T try ignore (of_list []); false with Empty -> true *) let enum node = let next e () = if not e.valid then raise BatEnum.No_more_elements else begin let rval = e.curr.data in e.curr <- e.curr.next; if (e.curr == node) then e.valid <- false; rval end and count e () = if not e.valid then 0 else let rec loop cnt n = if n == node then cnt else loop (cnt + 1) (n.next) in loop 1 (e.curr.next) in let rec clone e () = let e' = { curr = e.curr; valid = e.valid } in BatEnum.make ~next:(next e') ~count:(count e') ~clone:(clone e') in let e = { curr = node; valid = true } in BatEnum.make ~next:(next e) ~count:(count e) ~clone:(clone e) let rev_enum node = let prev e () = if not e.valid then raise BatEnum.No_more_elements else begin let rval = e.curr.data in e.curr <- e.curr.prev; if (e.curr == node) then e.valid <- false; rval end and count e () = if not e.valid then 0 else let rec loop cnt n = if n == node then cnt else loop (cnt + 1) (n.prev) in loop 1 (e.curr.prev) in let rec clone e () = let e' = { curr = e.curr; valid = e.valid } in BatEnum.make ~next:(prev e') ~count:(count e') ~clone:(clone e') in let e = { curr = node; valid = true } in BatEnum.make ~next:(prev e) ~count:(count e) ~clone:(clone e) let backwards t = rev_enum (prev t) let of_enum enm = match BatEnum.get enm with | None -> raise Empty | Some(d) -> let first = create d in let f n d = append n d in ignore(BatEnum.fold f first enm); first let print ?(first="[") ?(last="]") ?(sep="; ") print_a out t = BatEnum.print ~first ~last ~sep print_a out (enum t) let filter f node = (*TODO : make faster*) of_enum (BatEnum.filter f (enum node)) let filter_map f node = (*TODO : make faster*) of_enum (BatEnum.filter_map f (enum node))